YOSEMITE JANUARY, 1979 VOLUME FORTY-SEVEN, NUMBER 5 Published for members of Yosemite Natural History Association YOSEMITE VALLEY A. LOWER CHAMBER F . INDIAN CREEK K . SENTINEL CREEK B. CENTRAL CHAMBER G . YOSEMITE CREEK L . ILLILOUTTE CREEK C. UPPER CHAMBER H . RIBBON CREEK M . MEDIAL MORAINE SCALE : 1 :15,840 D. MERCED RIVER I . FIREPLACE CREEK N . EL CAPITAN MORAINE J .F .M . 78 E. TENAYA CREEK J . BRIDALVEIL CREEK Yosemite Valley's Forgotten Natural Process: The Stream System YOSEMITE VALLEY'S STREAM SYSTEM IS UNIQUE . Where else in the world do waterfalls or cascades like the Yosemite, Nevada, Vernal, Bridalveil, Ribbon, Staircase or Tenaya pour over massive granite cliffs, down through narrow gorges to feed a stream system which lies on an almost level valley floor of huge meadows and encroaching forest of oak, pine, and cedar? The Merced River has flowed through Yosemite Valley for thousands of years, even before the time of the glacial advances which were responsible for creating these famous landform features which hang on the Valley walls today . Following the glacial retreat some ten thou- sand years ago, the pristine aboriginal streams of Yosemite Valley had the appearance of a dynamic system . Rapidly eroding stream banks sloughing off into the shallow stream channel, the streams transporting the alluvium , between the numerous mid-channel islands and even- tually depositing them on the point bars 2 or one of the many timber debris jams . Huge under- mined Black Oaks and Alders could be seen hanging over steep stream bank providing cool shade which oxbows and low lying meadow lands flooded with backwater, built up behind the El Capital Moraine . All these features of the riverian environment contributed to the crea- tion of the Valley floor as it was seen during the time of white discovery in 1851. Since the retreat of the Yosemite Glaciers, the stream system of the Valley has passed through a sequence of orderly events . A summary of the events which led to the formation of the Valley's stream system in 1851, is as follows: STAGE ONE : Filling of Ancient Lake Yosemite. Fed by the Tioga and Tenaya stage glaciers, Tenaya Creek and the Merced River were mainly responsible for the filling in of the ancient lake basin in the Central Chamber . Through coalescing of the streams and expanding deltas, a continuous plain of stream sediments even- tually filled the ancient lake to the crest of the El Capitan Moraine. PAST STREAM CHARACTERISTICS YOSEMITE VALLEY SINUOUS MEANDERING BRAIDED STAGE TWO STAGE THREE STAGE FOUR STAGE TWO : The Merced River a Sinuous Channel. Throughout a relatively short period of time, a series of breaches in the moraine dam stimulated stream rejuvenation . The river cut down through the old delta plain some fifteen feet. This caused a change in channel morphology' . The Merced River now devoted most of its energy to vertical erosion and as a result its sinuosity decreased . The Merced River developed a large gently curving channel, made up of long straight reaches. STAGE THREE : The Merced River, a Meandering Stream. As the Merced River approached its new base level, stream sinuousity increased since a lower gradient had developed . The river slowly began to evolve from a sinuous channel 4 to a meandering channel s. Stream degradation (down cutting) still occurred, however, lateral migration of the river flourished . During this fluvially active period the final stages of the new floodplain construction were completed. STAGE FOUR : Braided Stream& Patterns Develop. The Merced River, not able to down cut any further since large boulders blocked the river gap in the Moraine dam, could only migrate laterally . Sediments from accelerating bank ero- sion in addition to annual flood deposits, overwhelmed the stream's capacity to transport, resulting in a shift in channel morphology from a meandering stream to predominantly braided channel conditions. In many locations, the river spread out and divided by forming mid-channel point bars composed of alluvial sand and gravel . This condition existed in the lower four of the five and one-half miles of the Central Chamber . This change in channel morphology coincides with the coming of modern man to Yosemite Valley in 1851. For the next twenty-eight years Yosemite Valley maintained a natural riverscape appearance. One of the most noticeable conditions were the swampy meadow lands which existed in the lower end of the Central Chamber . The combination of permanent rock dams formed by glacial moraines and the numerous log-jams found throughout the natural riverscape were largely responsible for contributing to swampy meadow conditions . The most important and permanent cause of the swampy meadows on the Valley floor was the El Capital Moraine. This landform left by the glacial advances, controlled the base level of erosion and in- fluenced surface water drainage. It was not until 1879 that the stream system was seriously disturbed by modern man . An early guardian of Yosemite Valley named Galen Clark, succeeded to alter the elevation of the base-level, lowered the water table, increased surface drainage and initiated channel degrada- tion in the Central Chamber . Early accounts of Yosemite Valley describe the meadow lands as being swampy . Galen Clark realized the influence of the El Capital Moraine on the hydrology of the Central Chamber . In an attempt to open potential grazing land, and access to various areas of the Valley, Clark, in 1879, found a quick and sure method of draining the low lying meadows. The following letter written by Clark in 1907, titled "Cause of Swift Erosion," describes the incident. It may be interesting to the public to know the cause of there being in recent years so much more activity in the river currents cutting away the river banks than during the earlier known history of Yosemite. When the El Capital bridge was built in 1879, it was located across the narrow channel of the river between the two points of what remains of an old glacial terminal moraine. The river channel at this place was filled with large boulders, which greatly obstructed the free outflow of the flood waters in the spring, causing extensive overflows of the low meadow land above, greatly interfering with travel, especially to Yosemite Falls and Mirror Lake. In order to remedy this matter, the large boulders in the river channel were blasted and the fragments leveled down so as to give a free outflow of the flood waters. This increased the flow of the river currents, which now commenced greater eroding work on the river banks, and as the winding turns became more abrupt the destructive force annually increases. Some thorough system of protection should be promptly used to save the river banks from further damage. A detailed study of the El Capitan Moraine dam was completed during the Fall of 1977 . Tak- ing advantage of the low water during this drought year, the observations revealed the loca- tion of where Galen Clark blasted the moraine boulders in order to increase surface drainage and lower the water table . The study determined the width, length and depth of the blasted area. By measuring boulder fragments, tributary stream terrace levels, conifer hierarchy' on the stream terrace levels and surveying of six cross-sections of the Valley floor, the original height of the El Capitan Moraine prior to the blasting was determined . Since 1879, tributary stream channels have down-cut to an average depth of 4 .5 feet . This means that the present river gap in the El Capitan Moraine must be 4 .5 lower than in 1879 prior to Clark's blasting. This figure is important because the river-gap elevation represents the base-level of erosion for the entire Central Chamber . Since 1879, the stream system's accelerated rate of degrada- tion above the moraine has remained unchecked. Photographs taken of Yosemite Valley by Watkins and Fiske in 1866, fifteen years before the El Capitan Moraine was blasted, show photo after photo of heavily eroded stream banks five to six feet high, undermining trees and exposing roots of tall pines, cedars and oaks. Throughout geologic time, Yosemite Valley's stream system in the Central Chamber re- peatedly shifted its channel . Oxbow bends, abandoned stream channels and sloughs scar the floors of every large meadow in Yosemite Valley . Swampy meadows developed in the depres- sions of the fluvial scars . Stream bank erosion was as much a part of the aboriginal landscape in Yosemite Valley as the waterfalls. Despite the fact that the processes of lateral erosion were normal, early guardians and the managing Board of Commissioners for Yosemite saw this natural phenomena as destructive to Yosemite meadows . In all actuality, no one noticed the river's dynamic character until it began to undermine bridges, roads and lodges constructed in the meander belt of the stream system . Galen Clark had begun the campaign of altering the pristine aboriginal riverscape by rejuvenating stream degradation, while the Commission sought methods to halt lateral erosion. In 1882, the State Engineer, W . Hall, visited Yosemite Valley and inspected the river system to suggest improvements at the Commissioners request. The following quotes are from his pamphlet, "To preserve from defacement and promote use of the Yosemite Valley" (1882). The following quotations document that braided reaches of channel existed and that numerous amounts of logs and unchecked lateral erosion were natural features in the riverscape. several notable obstructions lay in the river channel. Waters must be brought into one channel. above the Upper Iron Bridge, I found the river channel to be in especially bad condition, in fact, it divided up, spread out, obstructed and torturous in its course. result in unregulated overflow of large portions of available meadow lands in the Valley.
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